Thermodynamic geometry of Ising ferromagnet in an external magnetic field: A self-consistent field theory calculation

We present a complete geometrical description for the ferromagnetic Ising model in the pair approximation as introduced by Balcerzak (2003) using self-consistent field theory. A metric is defined in a two-dimensional phase space of magnetization (M) and nearest-neighbour correlation function (C). Ba...

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Bibliographic Details
Published in:Physica A 2019-07, Vol.526, p.121173, Article 121173
Main Author: Erdem, Rıza
Format: Article
Language:English
Subjects:
Ferromagnetic Ising model
Pair approximation
Self-consistent field theory
Thermodynamic curvature
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Summary:We present a complete geometrical description for the ferromagnetic Ising model in the pair approximation as introduced by Balcerzak (2003) using self-consistent field theory. A metric is defined in a two-dimensional phase space of magnetization (M) and nearest-neighbour correlation function (C). Based on the metric elements an expression for the thermodynamic Ricci scalar (R) is derived in terms of the lattice coordination number q. We study R as the temperature (T), magnetic field (h) and exchange energy coupling (J) are varied and show that there are T and h dependent critical properties for q=6. By direct comparison, we demonstrate that the special case q=2 provides a consistent behaviour with the already known exact formula in Janyszek and Mrugała work (1989) for the one-dimensional Ising model. •We present thermodynamic geometry of ferromagnetic Ising model.•We introduce a metric in the phase space of magnetization versus spin correlation.•We use this metric to calculate the thermodynamic curvature scalar.•Continuous/discontinuous phase transitions of the system are studied using the curvature scalar in the presence of external magnetic field.
ISSN:0378-4371
1873-2119
DOI:10.1016/j.physa.2019.121173